The present invention is provided with: a mounting body mounted on an axle; a ring-shaped body (13) surrounding the mounting body from an outside in a tire radial direction; a connecting member (15) configured to connect the mounting body and the ring-shaped body (13) such that the mounting body and the ring-shaped body (13) are displaceable; and a cylindrical tread member (16) mounted over the ring-shaped body (13), wherein grooves (51, 52) are formed at an outer peripheral surface of a portion located above and corresponding to a portion of the tread member (16) at which the ring-shaped body (13) and the connecting member (15) are connected.

A variable compliance non-pneumatic wheel which comprises a stationary tubular body (32) attached to the vehicle chassis. A tubular member is freely rotatable relative to the stationary tubular body and has a series of peripheral mounting rods (12, 13) on sides of the wheel. A plurality of interconnected and freely rotating caterpillar-like tiles (5), which are in contact with the ground during wheel operation, are coupled to the outer periphery of the wheel. A plurality of connecting spring members, (3, 4, 6, 7, 8, 9, 10, 11), each connecting a specific mounting rod on a side of the hub (1, 2) are configured to connect the tiles (5) to the hub. The tubular member is split in two parts (1, 2) which are each free to rotate relative to one another. Each part carries approximately half number of mounting rods and connecting springs on a respective side of the wheel.

A system for adjusting the compliance of a wheel is provided. In one embodiment, wheel segments are adjusted, causing the stiffness of the wheel to change. Such adjustments can be made while the wheel is rotating, allowing the wheel compliance to be changed while a vehicle is in motion.

A system for adjusting the compliance of a wheel is provided. In one embodiment, wheel segments are adjusted, causing the stiffness of the wheel to change. Such adjustments can be made while the wheel is rotating, allowing the wheel compliance to be changed while a vehicle is in motion.

A non-pneumatic tire includes a wheel portion, a tread ring portion, a plurality of flexible spokes extending between and attached to the wheel portion and the tread ring portion, and plurality of bump stops positioned between the wheel portion and the tread ring portion. The bumps stops are configured to limit deformation and/or compressive strain of the plurality of flexible spokes. The plurality of bump stops includes a plurality of tower bump stops, a plurality of triangular-shaped bump stops, and/or a plurality of roof-top shaped bump stops.

A non-pneumatic tire includes a wheel portion, a tread ring portion, a plurality of flexible spokes extending between and attached to the wheel portion and the tread ring portion, and plurality of bump stops positioned between the wheel portion and the tread ring portion. The bumps stops are configured to limit deformation and/or compressive strain of the plurality of flexible spokes. The plurality of bump stops includes a plurality of tower bump stops, a plurality of triangular-shaped bump stops, and/or a plurality of roof-top shaped bump stops.

The present invention includes: an elastically deformable tire part (7) which includes an inner cylinder, an outer cylinder (4) configured to surround the inner cylinder from the outside in a tire radial direction, and a linking member (3) configured to link the inner cylinder to the outer cylinder (4) and a tread member (5) externally fitted onto the outer cylinder (4), wherein an elastic modulus of a material forming the tread member (5) is smaller than an elastic modulus of a material forming a tire part (7), an outer circumferential surface of the tread member (5) is formed in a curved shape in which the outer circumferential surface thereof protrudes outward in the tire radial direction when viewed in a vertical cross-sectional view in both a tire width direction and the tire radial direction, the outer cylinder (4) includes an outer circumferential section (41) positioned on a tire equatorial section, side sections (42) positioned on both sides in the tire width direction with respect to the outer circumferential section (41), and a shoulder section (43) configured to connect the outer circumferential section (41) to the side sections (42), the outer circumferential section (41) is formed in a straight line shape in which the outer circumferential section (41) extends in the tire width direction when viewed in the vertical cross-sectional view, and the shoulder section (43) gradually extends inward in the tire radial direction as it goes outward in the tire width direction.

A wheel includes a wheel rim, a hub defining a hollow housing for a wheel mount, and three or more resilient and equidistantly spaced spokes extending between an outer circumferential surface of the hub and an inner circumferential surface of the wheel rim. Each spoke is defined by a flexed, elongate spring element having a length that is greater than the radial distance between the outer circumferential surface of the hub and the inner circumferential surface of the wheel rim. The spring element is tangentially fixed at or towards one end to the outer circumferential surface of the hub and tangentially coupled at or towards its other end to the inner circumferential surface of the wheel rim via a hinged connection. The tangential coupling at the wheel rim is spaced circumferentially from the tangential fixing at the hub in a predetermined direction by a predetermined angle.

A wheel includes a wheel rim, a hub defining a hollow housing for a wheel mount, and three or more resilient and equidistantly spaced spokes extending between an outer circumferential surface of the hub and an inner circumferential surface of the wheel rim. Each spoke is defined by a flexed, elongate spring element having a length that is greater than the radial distance between the outer circumferential surface of the hub and the inner circumferential surface of the wheel rim. The spring element is tangentially fixed at or towards one end to the outer circumferential surface of the hub and tangentially coupled at or towards its other end to the inner circumferential surface of the wheel rim via a hinged connection. The tangential coupling at the wheel rim is spaced circumferentially from the tangential fixing at the hub in a predetermined direction by a predetermined angle.

A tire and wheel assembly includes a non-pneumatic tire and a wheel. The non-pneumatic tire incudes a tread, an inner liner, and a plurality of spokes extending between and coupling the tread to the inner liner. The plurality of spokes have a first width and the inner liner has a second width greater than the first width such that a pair of inner liner flanges extend beyond the plurality of spokes in an axial direction. The wheel includes a rim and the inner liner is configured to be mounted on the rim with the pair of inner liner flanges fastened to the rim such that the non-pneumatic tire is serviceably mounted on the wheel.